J. Woodward scite author profile

Targeted radiotherapies maximize cytotoxicty to cancer cells. In vivo α-generator targeted radiotherapies can deliver multiple α particles to a receptor site dramatically amplifying the radiation dose delivered to the target. The major challenge with α-generator radiotherapies is that traditional chelating moieties are unable to sequester the radioactive daughters in the bioconjugate which is critical to minimize toxicity to healthy, non-target tissue. The recoil energy of the 225Ac daughters following α decay will sever any metal-ligand bond used to form the bioconjugate. This work demonstrates that an engineered multilayered nanoparticle-antibody conjugate can deliver multiple α radiations and contain the decay daughters of 225Ac while targeting biologically relevant receptors in a female BALB/c mouse model. These multi-shell nanoparticles combine the radiation resistance of lanthanide phosphate to contain 225Ac and its radioactive decay daughters, the magnetic properties of gadolinium phosphate for easy separation, and established gold chemistry for attachment of targeting moieties.

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LaPO₄ Nanoparticles Doped with Actinium-225 that Partially Sequester Daughter Radionuclides

Woodward

Kennel

Stuckey

et al. 2011

Bioconjugate Chem.

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Nanoscale materials have been envisioned as carriers for various therapeutic drugs, including radioisotopes. Inorganic nanoparticles (NPs) are particularly appealing vehicles for targeted radiotherapy because they can package several radioactive atoms into a single carrier and can potentially retain daughter radioisotopes produced by in vivo generators such as actinium-225 ((225)Ac, t(1/2) = 10 d). Decay of this radioisotope to stable bismuth-209 proceeds through a chain of short-lived daughters accompanied by the emission of four α-particles that release >27 MeV of energy. The challenge in realizing the enhanced cytotoxic potential of in vivo generators lies in retaining the daughter nuclei at the therapy site. When (225)Ac is attached to targeting agents via standard chelate conjugation methods, all of the daughter radionuclides are released after the initial α-decay occurs. In this work, (225)Ac was incorporated into lanthanum phosphate NPs to determine whether the radioisotope and its daughters would be retained within the dense mineral lattice. Further, the (225)Ac-doped NPs were conjugated to the monoclonal antibody mAb 201B, which targets mouse lung endothelium through the vasculature, to ascertain the targeting efficacy and in vivo retention of radioisotopes. Standard biodistribution techniques and microSPECT/CT imaging of (225)Ac as well as the daughter radioisotopes showed that the NPs accumulated rapidly in mouse lung after intravenous injection. By showing that excess, competing, uncoupled antibodies or NPs coupled to control mAbs are deposited primarily in the liver and spleen, specific targeting of NP-mAb 201B conjugates was demonstrated. Biodistribution analysis showed that ∼30% of the total injected dose of La((225)Ac)PO(4) NPs accumulated in mouse lungs 1 h postinjection, yielding a value of % ID/g >200. Furthermore, after 24 h, 80% of the (213)Bi daughter produced from (225)Ac decay was retained within the target organ and (213)Bi retention increased to ∼87% at 120 h. In vitro analyses, conducted over a 1 month interval, demonstrated that ∼50% of the daughters were retained within the La((225)Ac)PO(4) NPs at any point over that time frame. Although most of the γ-rays from radionuclides in the (225)Ac decay chain are too energetic to be captured efficiently by SPECT detectors, appropriate energy windows were found that provided dramatic microSPECT images of the NP distribution in vivo. We conclude that La((225)Ac)PO(4)-mAb 201B conjugates can be targeted efficiently to mouse lung while partially retaining daughter products and that targeting can be monitored by biodistribution techniques and microSPECT imaging.

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“False” hope

et al. 2002

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"False" hope is condemned in the literature on the grounds that it reflects the counterproductive use of: (a) expectations based on illusions rather than reality, (b) inappropriate goals, and (c) poor strategies to reach desired goals. Snyder, Harris, et al.'s (1991) hope theory involving self-referential thoughts about finding routes to desired goals (pathways) and the motivation to use those routes (agency) is used as a framework for examining these three criticisms of false hope. It is concluded that the presently available evidence does not support any of the false-hope criticisms. The implications of hope-related issues for the applied clinical arena are discussed.

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Hope Against the Cold: Individual Differences in Trait Hope and Acute Pain Tolerance on the Cold Pressor Task

Snyder

Berg

Woodward

et al. 2005

Journal of Personality

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Hope theory (see Snyder, 1994) is presented as a useful framework for understanding reactions to pain. In Study 1, persons scoring higher on the trait Hope Scale (Snyder, Harris et al., 1991) kept their hands in the freezing water (of a cold pressor task) for significantly longer. In Study 2, the higher-hope males, and not females, as measured by both trait and state hope (Snyder, Sympson et al., 1996), recognized the onset of the pain threshold significantly later. Moreover, in Study 2, results showed that individual differences measures of optimism, self-efficacy, depression, and positive and negative affects did not relate to the pain onset and tolerance variables. The implications of hope as related to the pain process and related research are discussed.

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J. Woodward

Palladium-bacterial cellulose membranes for fuel cells

Gold Coated Lanthanide Phosphate Nanoparticles for Targeted Alpha Generator Radiotherapy

LaPO₄ Nanoparticles Doped with Actinium-225 that Partially Sequester Daughter Radionuclides

“False” hope

Hope Against the Cold: Individual Differences in Trait Hope and Acute Pain Tolerance on the Cold Pressor Task

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Product

Resources

About

J. Woodward

Palladium-bacterial cellulose membranes for fuel cells

Gold Coated Lanthanide Phosphate Nanoparticles for Targeted Alpha Generator Radiotherapy

LaPO4 Nanoparticles Doped with Actinium-225 that Partially Sequester Daughter Radionuclides

“False” hope

Hope Against the Cold: Individual Differences in Trait Hope and Acute Pain Tolerance on the Cold Pressor Task

Contact Info

Product

Resources

About

LaPO₄ Nanoparticles Doped with Actinium-225 that Partially Sequester Daughter Radionuclides